參考文獻 |
1. Lerman, M. J.; Lembong, J.; Muramoto, S.; Gillen, G.; Fisher, J. P. J. T. E. P. B. R., The evolution of polystyrene as a cell culture material. Tissue Engineering Part B: Reviews 2018, 24 (5), 359-372.
2. Merck ECM Gel Matrix: Protocols Using EHS Basement Membrane Extracts. https://www.sigmaaldrich.com/TW/en/technical-documents/technical-article/cell-culture-and-cell-culture-analysis/3d-cell-culture/ecm-gel-product-protocols.
3. UPM Biomedicals What is the difference between 2D versus 3D cell culture? https://www.upmbiomedicals.com/resource-center/learning-center/what-is-3d-cell-culture/2d-versus-3d-cell-culture/.
4. Costa, E. C.; Moreira, A. F.; de Melo-Diogo, D.; Gaspar, V. M.; Carvalho, M. P.; Correia, I. J. J. B. a., 3D tumor spheroids: an overview on the tools and techniques used for their analysis. Biotechnology Advances 2016, 34 (8), 1427-1441.
5. Langhans, S. A. J. F. i. p., Three-dimensional in vitro cell culture models in drug discovery and drug repositioning. 2018, 9, 6.
6. Ravi, M.; Paramesh, V.; Kaviya, S.; Anuradha, E.; Solomon, F. P. J. J. o. c. p., 3D cell culture systems: advantages and applications. Journal of Cellular Physiology 2015, 230 (1), 16-26.
7. Haisler, W. L.; Timm, D. M.; Gage, J. A.; Tseng, H.; Killian, T.; Souza, G. R. J. N. p., Three-dimensional cell culturing by magnetic levitation. Nature protocols 2013, 8 (10), 1940-1949.
8. Imamura, Y.; Mukohara, T.; Shimono, Y.; Funakoshi, Y.; Chayahara, N.; Toyoda, M.; Kiyota, N.; Takao, S.; Kono, S.; Nakatsura, T. J. O. r., Comparison of 2D-and 3D-culture models as drug-testing platforms in breast cancer. Oncology Reports 2015, 33 (4), 1837-1843.
9. Kapałczyńska, M.; Kolenda, T.; Przybyła, W.; Zajączkowska, M.; Teresiak, A.; Filas, V.; Ibbs, M.; Bliźniak, R.; Łuczewski, Ł.; Lamperska, K. J. A. o. M. S., 2D and 3D cell cultures–a comparison of different types of cancer cell cultures. State of the art paper 2018, 14 (4), 910-919.
10. AXION BIOSYSTEMS Spheroids: properties, image analysis, and culture methods. https://cytosmart.com/resources/resources/spheroids-properties-image-analysis-and-culture-methods#applicationsculture.
11. Ryu, N.-E.; Lee, S.-H.; Park, H. J. C., Spheroid culture system methods and applications for mesenchymal stem cells. MDPI cells 2019, 8 (12), 1620.
12. Fennema, E.; Rivron, N.; Rouwkema, J.; van Blitterswijk, C.; De Boer, J. J. T. i. b., Spheroid culture as a tool for creating 3D complex tissues. Trends in biotechnology 2013, 31 (2), 108-115.
13. Want, A. J.; Nienow, A. W.; Hewitt, C. J.; Coopman, K. J. R. m., Large-scale expansion and exploitation of pluripotent stem cells for regenerative medicine purposes: beyond the T flask. REGENERATIVE MEDICINEVOL. 2012, 7 (1), 71-84.
14. Corning Incorporated Life Sciences Corning Matrigel Matrix Frequently Asked Questions. https://www.corning.com/catalog/cls/documents/faqs/CLS-DL-CC-026.pdf.
15. Aisenbrey, E. A.; Murphy, W. L. J. N. R. M., Synthetic alternatives to Matrigel. Nature Reviews Materials 2020, 5 (7), 539-551.
16. Shen, M.; Horbett, T. A. J. J. o. B. M. R. A. O. J. o. T. S. f. B., The Japanese Society for Biomaterials,; Biomaterials, T. A. S. f.; Biomaterials, t. K. S. f., The effects of surface chemistry and adsorbed proteins on monocyte/macrophage adhesion to chemically modified polystyrene surfaces. Journal of Biomedical Materials Research 2001, 57 (3), 336-345.
17. Merck, Evolution of Cell Culture Surfaces.
18. Zhang, L. F.; Sun, R.; Xu, L.; Du, J.; Xiong, Z. C.; Chen, H. C.; Xiong, C. D. J. M. S.; C, E., Hydrophilic poly (ethylene glycol) coating on PDLLA/BCP bone scaffold for drug delivery and cell culture. 2008, 28 (1), 141-149.
19. Rajan, S.; Marimuthu, K.; Ayyanar, C. B.; Hoque, M. E. J. J. o. M. R.; Technology, Development and in-vitro characterization of HAP blended PVA/PEG bio-membrane. 2022, 18, 4956-4964.
20. Zhan, H.; Löwik, D. W. J. A. F. M., A hybrid peptide amphiphile fiber PEG hydrogel matrix for 3D cell culture. 2019, 29 (16), 1808505.
21. Branch, D. W.; Wheeler, B. C.; Brewer, G. J.; Leckband, D. E. J. B., Long-term stability of grafted polyethylene glycol surfaces for use with microstamped substrates in neuronal cell culture. 2001, 22 (10), 1035-1047.
22. BROADPHARM What is Polyethylene Glycol? https://broadpharm.com/blog/what-is-polyethylene-glycol.
23. Nkhwa, S.; Lauriaga, K. F.; Kemal, E.; Deb, S. In Poly (vinyl alcohol): physical approaches to designing biomaterials for biomedical applications, Conference Papers in Science, Hindawi: 2014.
24. Molyneaux, K.; Wnek, M. D.; Craig, S. E.; Vincent, J.; Rucker, I.; Wnek, G. E.; Brady‐Kalnay, S. M. J. J. o. B. M. R. P. B. A. B., Physically‐cross‐linked poly (vinyl alcohol) cell culture plate coatings facilitate preservation of cell–cell interactions, spheroid formation, and stemness. 2021, 109 (11), 1744-1753.
25. Dou, X.; Li, P.; Schönherr, H. J. B., Three-dimensional microstructured poly (vinyl alcohol) hydrogel platform for the controlled formation of multicellular cell spheroids. 2018, 19 (1), 158-166.
26. Gao, C.; Gao, Q.; Li, Y.; Rahaman, M. N.; Teramoto, A.; Abe, K. J. J. o. B. M. R. P. A., Preparation and in vitro characterization of electrospun PVA scaffolds coated with bioactive glass for bone regeneration. 2012, 100 (5), 1324-1334.
27. Kamoun, E. A.; Chen, X.; Eldin, M. S. M.; Kenawy, E.-R. S. J. A. J. o. c., Crosslinked poly (vinyl alcohol) hydrogels for wound dressing applications: A review of remarkably blended polymers. 2015, 8 (1), 1-14.
28. Jiang, S.; Liu, S.; Feng, W. J. J. o. t. m. b. o. b. m., PVA hydrogel properties for biomedical application. 2011, 4 (7), 1228-1233.
29. Mansur, H. S.; Costa Jr, E. d. S.; Mansur, A. A.; Barbosa-Stancioli, E. F. J. M. S.; C, E., Cytocompatibility evaluation in cell-culture systems of chemically crosslinked chitosan/PVA hydrogels. Materials Science and Engineering: C 2009, 29 (5), 1574-1583.
30. Kumar, A.; Han, S. S. J. I. j. o. p. m.; biomaterials, p., PVA-based hydrogels for tissue engineering: A review. 2017, 66 (4), 159-182.
31. Kamoun, E. A.; Kenawy, E.-R. S.; Chen, X. J. J. o. a. r., A review on polymeric hydrogel membranes for wound dressing applications: PVA-based hydrogel dressings. 2017, 8 (3), 217-233.
32. Almany, L.; Seliktar, D. J. B., Biosynthetic hydrogel scaffolds made from fibrinogen and polyethylene glycol for 3D cell cultures. Biomaterials 2005, 26 (15), 2467-2477.
33. BASF The Chemical Company, Kollicoat@IR.
34. Mittwollen, T. C. J.-P., Coating mit Kollicoat®. Easy Coating, pp 135–151.
35. Ehab A Fouad , M. E.-B., Steven H Neau, Fars K Alanazi, Ibrahim A Alsarra, Technology evaluation: Kollicoat IR. Expert Opinion on Drug Delivery 2011, Volume 8 (Issue 5), Pages 693-703.
36. Tirca, I.; Mitran, V.; Marascu, V.; Brajnicov, S.; Ion, V.; Stokker-Cheregi, F.; Popovici, I.; Cimpean, A.; Dinca, V.; Dinescu, M. J. A. S. S., In vitro testing of curcumin based composites coatings as antitumoral systems against osteosarcoma cells. 2017, 425, 1040-1051.
37. Janssens, S.; de Armas, H. N.; Remon, J. P.; Van den Mooter, G. J. E. j. o. p. s., The use of a new hydrophilic polymer, Kollicoat IR®, in the formulation of solid dispersions of Itraconazole. 2007, 30 (3-4), 288-294.
38. Ikada, Y. J. B., Surface modification of polymers for medical applications. 1994, 15 (10), 725-736.
39. Vogler, E. A. J. A. i. c.; science, i., Structure and reactivity of water at biomaterial surfaces. 1998, 74 (1-3), 69-117.
40. Ma, Z.; Mao, Z.; Gao, C. J. C.; Biointerfaces, S. B., Surface modification and property analysis of biomedical polymers used for tissue engineering. 2007, 60 (2), 137-157.
41. Chan, C.-M.; Ko, T.-M.; Hiraoka, H. J. S. s. r., Polymer surface modification by plasmas and photons. 1996, 24 (1-2), 1-54.
42. Chu, P. K.; Chen, J.; Wang, L.; Huang, N. J. M. S.; Reports, E. R., Plasma-surface modification of biomaterials. 2002, 36 (5-6), 143-206.
43. Mrsic, I.; Baeuerle, T.; Ulitzsch, S.; Lorenz, G.; Rebner, K.; Kandelbauer, A.; Chasse, T. J. A. S. S., Oxygen plasma surface treatment of polymer films—Pellethane 55DE and EPR-g-VTMS. 2021, 536, 147782.
44. Nemani, S. K.; Annavarapu, R. K.; Mohammadian, B.; Raiyan, A.; Heil, J.; Haque, M. A.; Abdelaal, A.; Sojoudi, H. J. A. M. I., Surface modification of polymers: methods and applications. Advanced Materials Interfaces 2018, 5 (24), 1801247.
45. Dong, Y.; Jin, G.; Hong, Y.; Zhu, H.; Lu, T. J.; Xu, F.; Bai, D.; Lin, M. J. A. a. m.; interfaces, Engineering the cell microenvironment using novel photoresponsive hydrogels. 2018, 10 (15), 12374-12389.
46. Singh, N. K.; Lee, D. S. J. J. o. C. R., In situ gelling pH-and temperature-sensitive biodegradable block copolymer hydrogels for drug delivery. 2014, 193, 214-227.
47. Tomatsu, I.; Peng, K.; Kros, A. J. A. d. d. r., Photoresponsive hydrogels for biomedical applications. Advanced Drug Delivery Reviews 2011, 63 (14-15), 1257-1266.
48. Ercole, F.; Davis, T. P.; Evans, R. A. J. P. C., Photo-responsive systems and biomaterials: photochromic polymers, light-triggered self-assembly, surface modification, fluorescence modulation and beyond. Polymer Chemistry 2010, 1 (1), 37-54.
49. Edahiro, J.-i.; Sumaru, K.; Tada, Y.; Ohi, K.; Takagi, T.; Kameda, M.; Shinbo, T.; Kanamori, T.; Yoshimi, Y. J. B., In situ control of cell adhesion using photoresponsive culture surface. 2005, 6 (2), 970-974.
50. Chen, G., Poly (vinyl alcohol)-micropatterned surfaces for manipulation of mesenchymal stem cell functions. In Methods in cell biology, Elsevier: 2014; Vol. 119, pp 17-33.
51. Wu, L.-C.; Tada, S.; Isoshima, T.; Serizawa, T.; Ito, Y. J. J. o. M. C. B., Photo-reactive polymers for the immobilisation of epidermal growth factors. 2023.
52. Yu-Sung Hsieh, Y.-J. L., Yi-San Chang, The Software Module Development of Fast Data Calculation in Ellipsometry for Single Layer Film. 科儀新知第三十三卷第六期 101.6. |